Peopling of the Americas

The peopling of the Americas began when Paleolithic hunter-gatherers (Paleo-Indians) entered North America from the North Asian Mammoth steppe via the Beringia land bridge, which had formed between northeastern Siberia and western Alaska due to the lowering of sea level during the Last Glacial Maximum (26,000 to 19,000 years ago).[2] These populations expanded south of the Laurentide Ice Sheet and spread rapidly southward, occupying both North and South America by 12,000 to 14,000 years ago.[3][4][5][6][7] The earliest populations in the Americas, before roughly 10,000 years ago, are known as Paleo-Indians. Indigenous peoples of the Americas have been linked to Siberian populations by proposed linguistic factors, the distribution of blood types, and in genetic composition as reflected by molecular data, such as DNA.[8][9]

Map of early human migrations based on the Out of Africa theory; figures are in thousands of years ago (kya).[1]

While there is general agreement that the Americas were first settled from Asia, the pattern of migration and the place(s) of origin in Eurasia of the peoples who migrated to the Americas remain unclear.[4] The traditional theory is that Ancient Beringians moved when sea levels were significantly lowered due to the Quaternary glaciation,[10][11] following herds of now-extinct Pleistocene megafauna along ice-free corridors that stretched between the Laurentide and Cordilleran ice sheets.[12] Another route proposed is that, either on foot or using boats, they migrated down the Pacific coast to South America as far as Chile.[13] Any archaeological evidence of coastal occupation during the last Ice Age would now have been covered by the sea level rise, up to a hundred metres since then.[14]

The precise date for the peopling of the Americas is a long-standing open question. While advances in archaeology, Pleistocene geology, physical anthropology, and DNA analysis have progressively shed more light on the subject, significant questions remain unresolved.[15][16] The "Clovis first theory" refers to the hypothesis that the Clovis culture represents the earliest human presence in the Americas about 13,000 years ago.[17] Evidence of pre-Clovis cultures has accumulated and pushed back the possible date of the first peopling of the Americas.[18][19][20][21] Academics generally believe that humans reached North America south of the Laurentide Ice Sheet at some point between 15,000 and 20,000 years ago.[15][18][22][23][24][25] Some new controversial archaeological evidence suggests the possibility that human arrival in the Americas may have occurred prior to the Last Glacial Maximum more than 20,000 years ago.[18][26][27][28][29][30]

The environment during the latest glaciation

edit

Emergence and submergence of Beringia

edit
 
Figure 1. Submergence of the Beringian land bridge with post-Last Glacial Maximum (LGM) rise in eustatic sea level.

During the Wisconsin glaciation, the Earth's ocean water was, to varying degrees over time, stored in glacier ice. As water accumulated in glaciers, the volume of water in the oceans correspondingly decreased, resulting in lowering of global sea level. The variation of sea level over time has been reconstructed using oxygen isotope analysis of deep sea cores, the dating of marine terraces, and high-resolution oxygen isotope sampling from ocean basins and modern ice caps. A drop of eustatic sea level by about 60 to 120 metres (200 to 390 ft) from present-day levels, commencing around 30,000 years Before Present (BP), created Beringia, a durable and extensive geographic feature connecting Siberia with Alaska.[31] With the rise of sea level after the Last Glacial Maximum (LGM), the Beringian land bridge was again submerged. Estimates of the final re-submergence of the Beringian land bridge based purely on present bathymetry of the Bering Strait and eustatic sea level curve place the event around 11,000 years BP (Figure 1). Ongoing research reconstructing Beringian paleogeography during deglaciation could change that estimate and possible earlier submergence could further constrain models of human migration into North America.[31]

Glaciers

edit
 
Potential extent of human survivability during the last glacial maximum

The onset of the Last Glacial Maximum after 30,000 years BP saw the expansion of alpine glaciers and continental ice sheets that blocked migration routes out of Beringia. By 21,000 years BP, and possibly thousands of years earlier, the Cordilleran and Laurentide ice sheets coalesced east of the Rocky Mountains, closing off a potential migration route into the center of North America.[32][33][34] Alpine glaciers in the coastal ranges and the Alaskan Peninsula isolated the interior of Beringia from the Pacific coast. Coastal alpine glaciers and lobes of Cordilleran ice coalesced into piedmont glaciers that covered large stretches of the coastline as far south as Vancouver Island and formed an ice lobe across the Straits of Juan de Fuca by 18,000 BP.[35][36] Coastal alpine glaciers started to retreat around 19,000 BP[37] while Cordilleran ice continued advancing in the Puget lowlands up to 16,800 BP.[36] Even during the maximum extent of coastal ice, unglaciated refugia persisted on present-day islands, that supported terrestrial and marine mammals.[34] As deglaciation occurred, refugia expanded until the coast became ice-free by 15,000 BP.[34] The retreat of glaciers on the Alaskan Peninsula provided access from Beringia to the Pacific coast by around 17,000 BP.[38] The ice barrier between interior Alaska and the Pacific coast broke up starting around 16,200 BP.[35] The ice-free corridor to the interior of North America opened between 13,000 and 12,000 BP.[32][33][34] Glaciation in eastern Siberia during the LGM was limited to alpine and valley glaciers in mountain ranges and did not block access between Siberia and Beringia.[31]

Climate and biological environments

edit
 
Vegetation cover at the Last Glacial Maximum period ~18,000 years ago, describing the type of vegetation cover present

The paleoclimates and vegetation of eastern Siberia and Alaska during the Wisconsin glaciation have been deduced from high resolution oxygen isotope data and pollen stratigraphy.[31][39][40] Prior to the Last Glacial Maximum, climates in eastern Siberia fluctuated between conditions approximating present day conditions and colder periods. The pre-LGM warm cycles in Arctic Siberia saw flourishes of megafaunas.[31] The oxygen isotope record from the Greenland Ice Cap suggests that these cycles after about 45,000 BP lasted anywhere from hundreds to between one and two thousand years, with greater duration of cold periods starting around 32,000 BP.[31] The pollen record from Elikchan Lake, north of the Sea of Okhotsk, shows a marked shift from tree and shrub pollen to herb pollen prior to 30,000 BP, as herb tundra replaced boreal forest and shrub steppe going into the LGM.[31] A similar record of tree/shrub pollen being replaced with herb pollen as the LGM approached was recovered near the Kolyma River in Arctic Siberia.[40] The abandonment of the northern regions of Siberia due to rapid cooling or the retreat of game species with the onset of the LGM has been proposed to explain the lack of archaeological sites in that region dating to the LGM.[40][41] The pollen record from the Alaskan side shows shifts between herb/shrub and shrub tundra prior to the LGM, suggesting less dramatic warming episodes than those that allowed forest colonization on the Siberian side. Diverse, though not necessarily plentiful, megafauna were present in those environments. Herb tundra dominated during the LGM, due to cold and dry conditions.[39]

Coastal environments during the Last Glacial Maximum were complex. The lowered sea level, and an isostatic bulge equilibrated with the depression beneath the Cordilleran Ice Sheet, exposed the continental shelf to form a coastal plain.[42] While much of the coastal plain was covered with piedmont glaciers, unglaciated refugia supporting terrestrial mammals have been identified on Haida Gwaii, Prince of Wales Island, and outer islands of the Alexander Archipelago.[39] The now-submerged coastal plain has potential for more refugia.[39] Pollen data indicate mostly herb/shrub tundra vegetation in unglaciated areas, with some boreal forest towards the southern end of the range of Cordilleran ice.[39] The coastal marine environment remained productive, as indicated by fossils of pinnipeds.[42] The highly productive kelp forests over rocky marine shallows may have been a lure for coastal migration.[43][44] Reconstruction of the southern Beringian coastline also suggests potential for a highly productive coastal marine environment.[44]

Environmental changes during deglaciation

edit
 
A diagram of the formation of the Great Lakes

Pollen data indicate a warm period culminating between 17,000 and 13,000 BP followed by cooling between 13,000 and 11,500 BP.[42] Coastal areas deglaciated rapidly as coastal alpine glaciers, then lobes of Cordilleran ice, retreated. The retreat was accelerated as sea levels rose and floated glacial termini. It has been estimated that the coast range was fully ice-free between 16,000 and 15,000 BP.[42][34] Littoral marine organisms colonized shorelines as ocean water replaced glacial meltwater. Replacement of herb/shrub tundra by coniferous forests was underway by 15,000 BP north of Haida Gwaii. Eustatic sea level rise caused flooding, which accelerated as the rate grew more rapid.[42]

The inland Cordilleran and Laurentide ice sheets retreated more slowly than did the coastal glaciers. Opening of an ice-free corridor did not occur until after 13,000 to 12,000 BP.[32][33][34] The early environment of the ice-free corridor was dominated by glacial outwash and meltwater, with ice-dammed lakes and periodic flooding from the release of ice-dammed meltwater.[32] Biological productivity of the deglaciated landscape increased slowly.[34] The earliest possible viability of the ice-free corridor as a human migration route has been estimated at 11,500 BP.[34]

Birch forests were advancing across former herb tundra in Beringia by 17,000 BP in response to climatic amelioration, indicating increased productivity of the landscape.[40]

Analyses of biomarkers and microfossils preserved in sediments from Lake E5 and Burial Lake in northern Alaska suggest early humans burned Beringian landscapes as early as 34,000 years ago.[45][46] The authors of these studies suggest that fire was used as means of hunting megafauna.

Chronology, reasons for, and sources of migration

edit

The Indigenous peoples of the Americas have an ascertained archaeological presence in the Americas dating back to about 15,000 years ago.[47][48] More recent research, however, suggests a human presence dating to between 18,000 and 26,000 years ago, during the Last Glacial Maximum.[49][50][7] There remain uncertainties regarding the precise dating of individual sites and regarding conclusions drawn from population genetics studies of contemporary Native Americans.

Chronology

edit
 
Map of Beringia showing the exposed seafloor and glaciation at 40,000 years ago and 16,000 years ago. The green arrow indicates the "interior migration" model along an ice-free corridor separating the major continental ice sheets, the red arrow indicates the "coastal migration" model, both leading to a "rapid colonization" of the Americas after c. 16,000 years ago.[51]

In the early 21st century, the models of the chronology of migration are divided into two general approaches.[52][53]

The first is the short chronology theory, that the first migration occurred after the LGM, which went into decline after about 19,000 years ago,[37] and was then followed by successive waves of immigrants.[54]

The second theory is the long chronology theory, which proposes that the first group of people entered Beringia, including ice-free parts of Alaska, at a much earlier date, possibly 40,000 years ago,[55][56][57] followed by a much later second wave of immigrants.[53][58]

The Clovis First theory, which dominated thinking on New World anthropology for much of the 20th century, was challenged in the 2000s by the secure dating of archaeological sites in the Americas to before 13,000 years ago.[32][33][34][59][48]

The archaeological sites in the Americas with the oldest dates that have gained broad acceptance are all compatible with an age of about 15,000 years. This includes the Buttermilk Creek Complex in Texas,[47] the Meadowcroft Rockshelter site in Pennsylvania and the Monte Verde site in southern Chile.[48] Archaeological evidence of pre-Clovis people points to the South Carolina Topper Site being 16,000 years old, at a time when the glacial maximum would have theoretically allowed for lower coastlines.

It has often been suggested that an ice-free corridor, in what is now Western Canada, would have allowed migration before the beginning of the Holocene. However, a 2016 study has argued against this, suggesting that the peopling of North America via such a corridor is unlikely to significantly pre-date the earliest Clovis sites. The study concludes that the ice-free corridor in what is now Alberta and British Columbia "was gradually taken over by a boreal forest dominated by spruce and pine trees" and that the "Clovis people likely came from the south, not the north, perhaps following wild animals such as bison".[60][61] An alternative hypothesis for the peopling of America is coastal migration, which may have been feasible along the deglaciated (but now submerged) coastline of the Pacific Northwest from about 16,000 years ago.

Evidence for pre-LGM human presence

edit
 
Figure 2. Schematic illustration of maternal (mtDNA) gene-flow in and out of Beringia (long chronology, single source model).

Pre-LGM migration across Beringia has been proposed to explain purported pre-LGM ages of archaeological sites in the Americas such as Bluefish Caves[56] and Old Crow Flats[57] in the Yukon Territory, and Meadowcroft Rock Shelter in Pennsylvania.[53][58] The oldest archaeological sites on the Alaskan side of Beringia date to around 14,000 BP.[40][62] It is possible that a small founder population had entered Beringia before that time. However, archaeological sites that date closer to the LGM on either the Siberian or the Alaskan side of Beringia are lacking. Biomarker and microfossil analyses of sediments from Lake E5 and Burial Lake in northern Alaska suggest human presence in eastern Beringia as early as 34,000 years ago.[45] These sedimentary analyses have been suggested to be the only possibly recoverable remnants of humans living in Alaska during the last Glacial period.[46]

At Old Crow Flats, mammoth bones have been found that are broken in distinctive ways indicating human butchery. The radiocarbon dates on these vary between 25,000 and 40,000 BP. Also, stone microflakes have been found in the area indicating tool production.[63] However, the interpretations of butcher marks and the geologic association of bones at the Bluefish Cave and Old Crow Flats sites, and the related Bonnet Plume site, have been called into question.[29] No evidence of human remains have been discovered at these sites. In addition to disputed archaeological sites, support for pre-LGM human presence has been found in lake sediment records of northern Alaska. Biomarker and microfossil analyses of sediments from Lake E5 and Burial Lake in suggest human presence in eastern Beringia as early as 34,000 years ago.[45][46] These analyses are indeed compelling in that they corroborate the inferences made from the Bluefish Cave and Old Crow Flats sites.

In 2020, evidence emerged for a new pre-LGM site in North-Central Mexico. Chiquihuite cave, an archaeological site in Zacatecas State, has been dated to 26,000 years BP based on numerous lithic artefacts discovered there.[64] However, there is scholarly debate over whether the artifacts should be considered evidence of human activity or if they were formed naturally.[65][28] No evidence of human DNA or hearth have been unearthed.[66]

Pre-LGM human presence in South America rests partly on the chronology of the controversial Pedra Furada rock shelter in Piauí, Brazil. More recently, studies at the archaeological sites Santa Elina (27000-10000 years BP)[67] in the midwest, and Rincão I (20000-12000 years BP)[68] in southeastern Brazil also show associations of evidence of human presence with sediments dating from before the LGM. A 2003 study dated evidence for the controlled use of fire to before 40,000 years ago.[69] Additional evidence has been adduced from the morphology of Luzia Woman fossil, which was described as Australo-Melanesian. This interpretation was challenged in a 2003 review which concluded the features in question could also have arisen by genetic drift.[70] In November 2018, scientists of the University of São Paulo and Harvard University released a study that contradicts the alleged Australo-Melanesian origin of Luzia. Using DNA sequencing, the results showed that Luzia's ancestry was entirely Native American.[71][72]

Stones described as probable tools, hammerstones and anvils, have been found in southern California, at the Cerutti Mastodon site, that are associated with a mastodon skeleton which appeared to have been processed by humans. The mastodon skeleton was dated by thorium-230/uranium radiometric analysis, using diffusion–adsorption–decay dating models, to around 130 thousand years ago.[73] No human bones were found and expert reaction was mixed; claims of tools and bone processing were called "not plausible" by Prof. Tom Dillehay.[74]

The Yana River Rhino Horn site (RHS) has dated human occupation of eastern Arctic Siberia to 31,300 BP.[75] That date has been interpreted by some as evidence that migration into Beringia was imminent, lending credence to occupation of Beringia during the LGM.[76][77] However, the Yana RHS date is from the beginning of the cooling period that led into the LGM.[31] A compilation of archaeological site dates throughout eastern Siberia suggest that the cooling period caused a retreat of humans southwards.[40][41] Pre-LGM lithic evidence in Siberia indicate a settled lifestyle that was based on local resources, while post-LGM lithic evidence indicate a more migratory lifestyle.[41]

A 2021 discovery of human footprints in relict lake sediments near White Sands National Park in New Mexico demonstrated there was a verifiable human presence in the region dating back to the LGM between 18,000 and 26,000 years ago.[49][50] Later studies, reported in October 2023, confirmed that the age of the human footprints to be "up to 23,000 years old".[78][79]

The Clovis-first advocates have not accepted the veracity of these findings. In 2022, they said, "The oldest evidence for archaeological sites in the New World with large numbers of artifacts occurring in discrete and minimally disturbed stratigraphic contexts occur in eastern Beringia between 13,000 and 14,200 BP. South of the ice sheets, the oldest such sites occur in association with the Clovis complex. If humans managed to breach the continental ice sheets significantly before 13,000 BP, there should be clear evidence for it in the form of at least some stratigraphically discrete archaeological components with a relatively high artifact count. So far, no such evidence exists."[80]

Genomic age estimates

edit
 
Map of Y-Chromosome Haplogroups – dominant haplogroups in pre-colonial populations with proposed migrations routes

Genetic studies have used high resolution analytical techniques applied to DNA samples from modern Native Americans and Asian populations regarded as their source populations to reconstruct the development of human Y-chromosome DNA haplogroups (yDNA haplogroups) and human mitochondrial DNA haplogroups (mtDNA haplogroups) characteristic of Native American populations.[55][76][77] Models of molecular evolution rates were used to estimate the ages at which Native American DNA lineages branched off from their parent lineages in Asia and to deduce the ages of demographic events. One model (Tammetal 2007) based on Native American mtDNA Haplotypes (Figure 2) proposes that migration into Beringia occurred between 30,000 and 25,000 BP, with migration into the Americas occurring around 10,000 to 15,000 years after isolation of the small founding population.[76] Another model (Kitchen et al. 2008) proposes that migration into Beringia occurred approximately 36,000 BP, followed by 20,000 years of isolation in Beringia.[77] A third model (Nomatto et al. 2009) proposes that migration into Beringia occurred between 40,000 and 30,000 BP, with a pre-LGM migration into the Americas followed by isolation of the northern population following closure of the ice-free corridor.[55] Evidence of Australo-Melanesians admixture in Amazonian populations was found by Skoglund and Reich (2016).[81]

A study of the diversification of mtDNA Haplogroups C and D from southern Siberia and eastern Asia, respectively, suggests that the parent lineage (Subhaplogroup D4h) of Subhaplogroup D4h3, a lineage found among Native Americans and Han Chinese,[82][83] emerged around 20,000 BP, constraining the emergence of D4h3 to post-LGM.[84] Age estimates based on Y-chromosome micro-satellite diversity place origin of the American Haplogroup Q1a3a (Y-DNA) at around 15,000 to 10,000 BP.[85] Greater consistency of DNA molecular evolution rate models with each other and with archaeological data may be gained by the use of dated fossil DNA to calibrate molecular evolution rates.[82]

The Ancient Beringian (AB) is a human archaeogenetic lineage, based on the genome of an infant found at the Upward Sun River site (dubbed USR1), dated to 11,500 years ago.[86] The AB lineage diverged from the Ancestral Native American (ANA) lineage about 20,000 years ago. The ANA lineage was estimated as having been formed between 20,000 and 25,000 years ago by a mixture of East Asian (~65%) and Ancient North Eurasian (~35%) lineages, consistent with the model of the peopling of the Americas via Beringia during the Last Glacial Maximum.[87][88][89]

Megafaunal migrations

edit

Although there is no archaeological evidence that can be used to direct support a coastal migration route during the Last Glacial Maximum, genetic analysis has been used to support this thesis. In addition to human genetic lineage, megafaunal DNA lineage can be used to trace movements of megafauna – large mammalian – as well as the early human groups who hunted them.

Bison, a type of megafauna, have been identified as an ideal candidate for the tracing of human migrations out of Europe because of both their abundance in North America as well as being one of the first megafauna for which ancient DNA was used to trace patterns of population movement. Unlike other types of fauna that moved between the Americas and Eurasia (mammoths, horses, and lions), Bison survived the North American extinction event that occurred at the end of the Pleistocene. Their genome, however, contains evidence of a bottleneck – something that can be used to test hypothesis on migrations between the two continents.[90] Early human groups were largely nomadic, relying on following food sources for survival. Mobility was part of what made humans successful. As nomadic groups, early humans likely followed the food from Eurasia to the Americas – part of the reason why tracing megafaunal DNA is so helpful for garnering insight to these migratory patterns.[91]

The grey wolf originated in the Americas and migrated into Eurasia prior to the Last Glacial Maximum – during which it was believed that remaining populations of the grey wolf residing in North America faced extinction and were isolated from the rest of the population. This, however, may not be the case. Radiocarbon dating of ancient grey wolf remains found in permafrost deposits in Alaska show a continuous exchange of population from 12,500 radiocarbon years BP to beyond radiocarbon dating capabilities. This indicates that there was viable passage for grey wolf populations to exchange between the two continents.[92]

These faunas' ability to exchange populations during the period of the Last Glacial Maximum along with genetic evidence found from early human remains in the Americas provides evidence to support pre-Clovis migrations into the Americas.

Source populations

edit

The Native American source population was formed in Siberia by the mixing of two distinct populations: Ancient North Eurasians and an ancient East Asian (ESEA) population.[93][94] According to Jennifer Raff, the Ancient North Eurasian population mixed with a daughter population of ancient East Asians, who they encountered around 25,000 years ago, which led to the emergence of Native American ancestral populations. However, the exact location where the admixture took place is unknown, and the migratory movements that united the two populations are a matter of debate.[95]

One theory supposes that Ancient North Eurasians migrated south to East Asia, or Southern Siberia, where they would have encountered and mixed with ancient East Asians. Genetic evidence from Lake Baikal in Russia supports this area as the location where the admixture took place.[96]

However, a third theory, the "Beringian standstill hypothesis", suggests that East Asians instead migrated north to Northeastern Siberia, where they mixed with ANE, and later diverged in Beringia, where distinct Native American lineages formed. This theory is supported by maternal and nuclear DNA evidence.[97] According to Grebenyuk, after 20,000 BP, a branch of Ancient East Asians migrated to Northeastern Siberia, and mixed with descendants of the ANE, leading to the emergence of Ancient Paleo-Siberian and Native American populations in Extreme Northeastern Asia.[98]

However, the Beringian standstill hypothesis is not supported by paternal DNA evidence, which may reflect different population histories for paternal and maternal lineages in Native Americans, which is not uncommon and has been observed in other populations.[99]

A 2019 study suggested that Native Americans are the closest living relatives to 10,000-year-old fossils found near the Kolyma River in northeastern Siberia.[100]

A study published in July 2022 suggested that people in southern China may have contributed to the Native American gene pool, based on the discovery and DNA analysis of 14,000-year-old human fossils.[101][102]

The contrast between the genetic profiles of the Hokkaido Jōmon skeletons and the modern Ainu illustrates another uncertainty in source models derived from modern DNA samples.[103]

Mitochondrial (mtDNA) lineages

edit

The development of high-resolution genomic analysis has provided opportunities to further define Native American subclades and narrow the range of Asian subclades that may be parent or sister subclades.

The common occurrence of the mtDNA Haplogroups A, B, C, and D among eastern Asian and Native American populations has long been recognized, along with the presence of haplogroup X.[104] As a whole, the greatest frequency of the four Native American associated haplogroups occurs in the Altai-Baikal region of southern Siberia.[105] Some subclades of C and D closer to the Native American subclades occur among Mongolian, Amur, Japanese, Korean, and Ainu populations.[104][106]

With further definition of subclades related to Native American populations, the requirements for sampling Asian populations to find the most closely related subclades grow more specific. Subhaplogroups D1 and D4h3 have been regarded as Native American specific based on their absence among a large sampling of populations regarded as potential descendants of source populations, over a wide area of Asia.[76] Among the 3,764 samples, the Sakhalin–lower Amur region was represented by 61 Oroks.[76] In another study, Subhaplogroup D1a has been identified among the Ulchis of the lower Amur River region (4 among 87 sampled, or 4.6%), along with Subhaplogroup C1a (1 among 87, or 1.1%).[106] Subhaplogroup C1a is regarded as a close sister clade of the Native American Subhaplogroup C1b.[106]

Subhaplogroup D1a has also been found among ancient Jōmon skeletons from Hokkaido[103] The modern Ainu are regarded as descendants of the Jōmon.[103] The occurrence of the Subhaplogroups D1a and C1a in the lower Amur region suggests a source population from that region distinct from the Altai-Baikal source populations, where sampling did not reveal those two particular subclades.[106] The conclusions regarding Subhaplogroup D1 indicating potential source populations in the lower Amur[106] and Hokkaido[103] areas stand in contrast to the single-source migration model.[55][76][77]

Subhaplogroup D4h3 has been identified among Han Chinese.[82][83] Subhaplogroup D4h3 from China does not have the same geographic implication as Subhaplotype D1a from Amur-Hokkaido, so its implications for source models are more speculative. Its parent lineage, Subhaplotype D4h, is believed to have emerged in East Asia, rather than Siberia, around 20,000 BP.[84] Subhaplogroup D4h2, a sister clade of D4h3, has also been found among Jōmon skeletons from Hokkaido.[107] D4h3 has a coastal trace in the Americas.[83]

X is one of the five mtDNA haplogroups found in Indigenous Americans. Native Americans mostly belong to the X2a clade, which has never been found in the Old World.[108] According to Jennifer Raff, X2a probably originated in the same Siberian population as the other four founding maternal lineages, and that there is no compelling reason to believe it is related to X lineages found in Europe or West Eurasia. The Kennewick man fossil was found to carry the deepest branch of the X2a haplogroup, and he did not have any European ancestry that would be expected for a European origin of the lineage.[109]

HTLV-1 genomics

edit

The Human T cell Lymphotrophic Virus 1 (HTLV-1) is a virus transmitted through exchange of bodily fluids and from mother to child through breast milk. The mother-to-child transmission mimics a hereditary trait, although such transmission from maternal carriers is less than 100%.[110] The HTLV virus genome has been mapped, allowing identification of four major strains and analysis of their antiquity through mutations. The highest geographic concentrations of the strain HLTV-1 are in sub-Saharan Africa and Japan.[111] In Japan, it occurs in its highest concentration on Kyushu.[111] It is also present among African descendants and native populations in the Caribbean region and South America.[111] It is rare in Central America and North America.[111] Its distribution in the Americas has been regarded as due to importation with the slave trade.[112]

The Ainu have developed antibodies to HTLV-1, indicating its endemicity to the Ainu and its antiquity in Japan.[113] A subtype "A" has been defined and identified among the Japanese (including Ainu), and among Caribbean and South American isolates.[114] A subtype "B" has been identified in Japan and India.[114] In 1995, Native Americans in coastal British Columbia were found to have both subtypes A and B.[115] Bone marrow specimens from an Andean mummy about 1500 years old were reported to have shown the presence of the A subtype.[116] The finding ignited controversy, with contention that the sample DNA was insufficiently complete for the conclusion and that the result reflected modern contamination.[117] However, a re-analysis indicated that the DNA sequences were consistent with, but not definitely from, the "cosmopolitan clade" (subtype A).[117] The presence of subtypes A and B in the Americas is suggestive of a Native American source population related to the Ainu ancestors, the Jōmon.

Physical anthropology

edit

Paleo-Indian skeletons in the Americas such as Kennewick Man (Washington State), Hoya Negro skeleton (Yucatán), Luzia Woman and other skulls from the Lagoa Santa site (Brazil), Buhl Woman (Idaho), Peñon Woman III,[118] two skulls from the Tlapacoya site (Mexico City),[118] and 33 skulls from Baja California[119] have exhibited certain craniofacial traits distinct from most modern Native Americans, leading physical anthropologists to posit an earlier "Paleoamerican" population wave.[120] The most basic measured distinguishing trait is the dolichocephaly of the skull. Some modern isolated populations such as the Pericúes of Baja California and the Fuegians of Tierra del Fuego exhibit that same morphological trait.[119]

Other anthropologists advocate an alternative hypothesis that evolution of an original Beringian phenotype gave rise to a distinct morphology that was similar in all known Paleoamerican skulls, followed by later convergence towards the modern Native American phenotype.[121][122]

Archaeogenetic studies do not support a two-wave model or the Paleoamerican hypothesis of an Australo-Melanesian origin, and firmly assign all Paleo-Indians and modern Native Americans to one ancient population that entered the Americas in a single migration from Beringia. Only in one ancient specimen (Lagoa Santa) and a few modern populations in the Amazon region, a small Australasian ancestry component of c. 3% was detected, which remains unexplained by the current state of research (as of 2021), but may be explained by the presence of the more basal Tianyuan-related ancestry, a deep East Asian lineage which did not directly contribute to modern East Asians but may have contributed to the ancestors of Native Americans in Siberia, as such ancestry is also found among previous Paleolithic Siberians (Ancient North Eurasians).[81][123][93]

A report published in the American Journal of Physical Anthropology in January 2015 reviewed craniofacial variation focusing on differences between early and late Native Americans and explanations for these based on either skull morphology or molecular genetics. Arguments based on molecular genetics have in the main, according to the authors, accepted a single migration from Asia with a probable pause in Beringia, plus later bi-directional gene flow. Some studies focusing on craniofacial morphology have previously argued that Paleoamerican remains have been described as closer to Australo-Melanesians and Polynesians than to the modern series of Native Americans, suggesting two entries into the Americas, an early one occurring before a distinctive East Asian morphology developed (referred to in the paper as the "Two Components Model"). Another "third model", the "Recurrent Gene Flow" (RGF) model, attempts to reconcile the two, arguing that circumarctic gene flow after the initial migration could account for morphological changes. It specifically re-evaluates the original report on the Hoya Negro skeleton which supported the RGF model, the authors disagreed with the original conclusion which suggested that the skull shape did not match those of modern Native Americans, arguing that the "skull falls into a subregion of the morphospace occupied by both Paleoamericans and some modern Native Americans."[124]

Stemmed points

edit

Stemmed points are a lithic technology distinct from Beringian and Clovis types. They have a distribution ranging from coastal East Asia to the Pacific coast of South America.[43] The emergence of stemmed points has been traced to Korea during the upper Paleolithic.[125] The origin and distribution of stemmed points have been interpreted as a cultural marker related to a source population from coastal East Asia.[43]

Migration routes

edit

Interior route

edit
 
Map showing the approximate location of the ice-free corridor along the Continental Divide, separating the Cordilleran and Laurentide ice sheets. Also indicated are the locations of the Clovis and Folsom Paleo-Indian sites.

Clovis-First theory

edit

Historically, theories about migration into the Americas have revolved around migration from Beringia through the interior of North America. The discovery of artifacts in association with Pleistocene faunal remains near Clovis, New Mexico in the early 1930s required extension of the timeframe for the settlement of North America to the period during which glaciers were still extensive. That led to the hypothesis of a migration route between the Laurentide and Cordilleran ice sheets to explain the early settlement. The Clovis site was host to a lithic technology characterized by spear points with an indentation, or flute, where the point was attached to the shaft. A lithic complex characterized by the Clovis Point technology was subsequently identified over much of North America and in South America. The association of Clovis complex technology with late Pleistocene faunal remains led to the theory that it marked the arrival of big game hunters that migrated out of Beringia and then dispersed throughout the Americas, otherwise known as the Clovis First theory.

Recent radiocarbon dating of Clovis sites has yielded ages of between 13,000 and 12,600 BP, somewhat later than dates derived from older techniques.[126] The re-evaluation of earlier radiocarbon dates led to the conclusion that no fewer than 11 of the 22 Clovis sites with radiocarbon dates are "problematic" and should be disregarded, including the type site in Clovis, New Mexico. Numerical dating of Clovis sites has allowed comparison of Clovis dates with dates of other archaeological sites throughout the Americas, and of the opening of the ice-free corridor. Both lead to significant challenges to the Clovis First theory. The Monte Verde site of Southern Chile has been dated at 14,800 BP.[48] The Paisley Cave site in eastern Oregon yielded a 14,500 BP, on a coprolite with human DNA and radiocarbon dates of 13,200 and 12,900 BP on horizons containing western stemmed points.[127] Artifact horizons with non-Clovis lithic assemblages and pre-Clovis ages occur in eastern North America, although the maximum ages tend to be poorly constrained.[59][128]

Recent studies have suggested that the ice-free corridor opened later (around 13,800 ± 500 years ago) than the earliest widely accepted archaeological sites in the Americas, suggesting that it could have not have been used as the migration route for the earliest peoples to migrate south.[129]

An alternative to the Beringia route is proposed by the "stepping stones" hypothesis. The frequent submergence of islands along the Bering Transitory Archipelago would have forced the inhabitants of these island to continue traveling across the archipelago until they reached the mainland.[130]

Lithic evidence of pre-Clovis migrations

edit
 
1953 excavation of jasper projectile points from Deep Creek, Lake Mojave.

Geological findings on the timing of the ice-free corridor also challenge the notion that Clovis and pre-Clovis human occupation of the Americas was a result of migration through that route following the Last Glacial Maximum. Pre-LGM closing of the corridor may approach 30,000 BP and estimates of ice retreat from the corridor are in the range of 13,000 to 12,000 years ago.[32][33][34] Viability of the corridor as a human migration route has been estimated at 11,500 BP, later than the ages of the Clovis and pre-Clovis sites.[34] Dated Clovis archaeological sites suggest a south-to-north spread of the Clovis culture.[32]

Pre-LGM migration into the interior has been proposed to explain pre-Clovis ages for archaeological sites in the Americas,[53][58] although pre-Clovis sites such as Meadowcroft Rock Shelter,[59][128] Monte Verde,[48] and Paisley Cave have not yielded confirmed pre-LGM ages.

There are many pre-Clovis sites in the American Southwest, particularly in the Mojave Desert. Lake Mojave quarries dating back to the Pleistocene hold lithic remains of Silver Lake projectile points and Lake Mojave projectile points. This indicates an interior movement into the region as early as 13,800 BP, if not earlier.[131]

Dené–Yeniseian language family proposal

edit

A relationship between the Na-Dené languages of North America (such as Navajo and Apache), and the Yeniseian languages of Siberia was first proposed as early as 1923, and developed further by others. A detailed study was done by Edward Vajda and published in 2010.[132] This theory received support from many linguists, with archaeological and genetic studies providing it with further support.[citation needed]

The Arctic Small Tool tradition of Alaska and the Canadian Arctic may have originated in East Siberia about 5,000 years ago. This is connected with the ancient Paleo-Eskimo peoples of the Arctic.

The Arctic Small Tool tradition source may have been the Syalakh-Bel'kachi-Ymyakhtakh culture sequence of East Siberia, dated to 6,500–2,800 BP.[133]

The interior route is consistent with the spread of the Na-Dene language group[132] and subhaplogroup X2a into the Americas after the earliest paleoamerican migration.[83]

Nevertheless, some scholars suggest that the ancestors of western North Americans speaking Na-Dene languages made a coastal migration by boat.[134]

Earlier interior route

edit

It is possible that humans arrived in the Americas by way of interior routes that existed prior to the Last Glacial Maximum. Cosmogenic exposure dating, a technique that analyzes when in Earth's history a landscape was exposed to cosmic rays (and therefore unglaciated), performed by Mark Swisher suggests that an older ice-free corridor existed in North America 25,000 years ago. Swisher attributes sites such as Monte Verde, Meadowcroft Rockshelter, Manis Mastodon site and Paisley Caves to this corridor.[135]

Pacific coastal route

edit

The Pacific coastal migration theory proposes that people first reached the Americas via water travel, following coastlines from northeast Asia into the Americas, originally proposed in 1979 by Knute Fladmark as an alternative to the hypothetical migration through an ice-free inland corridor.[136] This model would help to explain the rapid spread to coastal sites extremely distant from the Bering Strait region, including sites such as Monte Verde in southern Chile and Taima-Taima in western Venezuela.

The very similar marine migration hypothesis is a variant of coastal migration; essentially its only difference is that it postulates that boats were the principal means of travel. The proposed use of boats adds a measure of flexibility to the chronology of coastal migration, because a continuous ice-free coast (16–15,000 calibrated years BP) would then not be required: Migrants in boats could have easily bypassed ice barriers and settled in scattered coastal refugia, before the deglaciation of the coastal land route was complete. A maritime-competent source population in coastal East Asia is an essential part of the marine migration hypothesis.[43][44]

A 2007 article in the Journal of Island and Coastal Archaeology proposed a "kelp highway hypothesis", a variant of coastal migration based on the exploitation of kelp forests along much of the Pacific Rim from Japan to Beringia, the Pacific Northwest, and California, and as far as the Andean Coast of South America. Once the coastlines of Alaska and British Columbia had deglaciated about 16,000 years ago, these kelp forest (along with estuarine, mangrove, and coral reef) habitats would have provided an ecologically homogenous migration corridor, entirely at sea level, and essentially unobstructed. A 2016 DNA analysis of plants and animals suggest a coastal route was feasible.[137][138]

Mitochondrial subhaplogroup D4h3a, a rare subclade of D4h3 occurring along the west coast of the Americas, has been identified as a clade associated with coastal migration.[83] This haplogroup was found in a skeleton referred to as Anzick-1, found in Montana in close association with several Clovis artifacts, dated 12,500 years ago.[139]

Problems with evaluating coastal migration models

edit

The coastal migration models provide a different perspective on migration to the New World, but they are not without their own problems: One such problem is that global sea levels have risen over 120 metres (390 ft)[140] since the end of the last glacial period, and this has submerged the ancient coastlines that maritime people would have followed into the Americas. Finding sites associated with early coastal migrations is extremely difficult—and systematic excavation of any sites found in deeper waters is challenging and expensive. Strategies for finding earliest migration sites include identifying potential sites on submerged paleoshorelines, seeking sites in areas uplifted either by tectonics or isostatic rebound, and looking for riverine sites in areas that may have attracted coastal migrants.[43][141] On the other hand, there is evidence of marine technologies found in the hills of the Channel Islands of California, circa 12,000 BP.[142] If there was an early pre-Clovis coastal migration, there is always the possibility of a "failed colonization".

See also

edit

References

edit
  1. ^ Burenhult, Göran (2000). Die ersten Menschen. Weltbild Verlag. ISBN 978-3-8289-0741-6.
  2. ^ Pringle, Heather (March 8, 2017). "What Happens When an Archaeologist Challenges Mainstream Scientific Thinking?". Smithsonian.
  3. ^ Fagan, Brian M. & Durrani, Nadia (2016). World Prehistory: A Brief Introduction. Routledge. p. 124. ISBN 978-1-317-34244-1.
  4. ^ a b Goebel, Ted; Waters, Michael R.; O'Rourke, Dennis H. (2008). "The Late Pleistocene dispersal of modern humans in the Americas" (PDF). Science. 319 (5869): 1497–1502. Bibcode:2008Sci...319.1497G. CiteSeerX 10.1.1.398.9315. doi:10.1126/science.1153569. PMID 18339930. S2CID 36149744. Archived from the original (PDF) on 2014-01-02. Retrieved 2010-02-05.
  5. ^ Zimmer, Carl (January 3, 2018). "In the Bones of a Buried Child, Signs of a Massive Human Migration to the Americas". The New York Times. Retrieved January 3, 2018.
  6. ^ Moreno-Mayar, JV; Potter, BA; Vinner, L; et al. (2018). "Terminal Pleistocene Alaskan genome reveals first founding population of Native Americans" (PDF). Nature. 553 (7687): 203–207. Bibcode:2018Natur.553..203M. doi:10.1038/nature25173. PMID 29323294. S2CID 4454580.
  7. ^ a b Núñez Castillo, Mélida Inés (2021-12-20). Ancient genetic landscape of archaeological human remains from Panama, South America and Oceania described through STR genotype frequencies and mitochondrial DNA sequences. Dissertation (doctoralThesis). doi:10.53846/goediss-9012. S2CID 247052631.
  8. ^ Ash, Patricia J. & Robinson, David J. (2011). The Emergence of Humans: An Exploration of the Evolutionary Timeline. John Wiley & Sons. p. 289. ISBN 978-1-119-96424-7.
  9. ^ Roberts, Alice (2010). The Incredible Human Journey. A&C Black. pp. 101–103. ISBN 978-1-4088-1091-0.
  10. ^ Fitzhugh, Drs. William; Goddard, Ives; Ousley, Steve; Owsley, Doug; Stanford, Dennis. "Paleoamerican". Smithsonian Institution Anthropology Outreach Office. Archived from the original on 2009-01-05. Retrieved 2009-01-15.
  11. ^ "Atlas of the Human Journey-The Genographic Project". National Geographic Society. 1996–2008. Archived from the original on 2011-05-01. Retrieved 2017-01-27.
  12. ^ "The peopling of the Americas: Genetic ancestry influences health". Scientific American. Retrieved 2019-05-08.
  13. ^ Fladmark, K. R. (1979). "Alternate Migration Corridors for Early Man in North America". American Antiquity. 44 (1): 55–69. doi:10.2307/279189. JSTOR 279189. S2CID 162243347.
  14. ^ "68 Responses to "Sea will rise 'to levels of last Ice Age'"". Center for Climate Systems Research, Columbia University. 26 January 2009. Retrieved 2009-11-17.
  15. ^ a b Null (2022-06-27). "Peopling of the Americas". Proceedings of the National Academy of Sciences of the United States of America. Retrieved 2022-12-19.
  16. ^ Waguespack, Nicole (2012). "Early Paleoindians, from Colonization to Folsom". In Timothy R. Pauketat (ed.). The Oxford Handbook of North American Archaeology. Oxford University Press. pp. 86–95. ISBN 978-0-19-538011-8.
  17. ^ Surovell, T. A.; Allaun, S. A.; Gingerich, J. A. M.; Graf, K. E.; Holmes, C. D. (2022). "Late Date of human arrival to North America". PLOS ONE. 17 (4): e0264092. doi:10.1371/journal.pone.0264092. PMC 9020715. PMID 35442993.
  18. ^ a b c Yasinski, Emma (2022-05-02). "New Evidence Complicates the Story of the Peopling of the Americas". The Scientist Magazine. Retrieved 2022-12-19.
  19. ^ Ardelean, Ciprian F.; Becerra-Valdivia, Lorena; Pedersen, Mikkel Winther; Schwenninger, Jean-Luc; Oviatt, Charles G.; Macías-Quintero, Juan I.; Arroyo-Cabrales, Joaquin; Sikora, Martin; Ocampo-Díaz, Yam Zul E.; Rubio-Cisneros, Igor I.; Watling, Jennifer G.; De Medeiros, Vanda B.; De Oliveira, Paulo E.; Barba-Pingarón, Luis; Ortiz-Butrón, Agustín; Blancas-Vázquez, Jorge; Rivera-González, Irán; Solís-Rosales, Corina; Rodríguez-Ceja, María; Gandy, Devlin A.; Navarro-Gutierrez, Zamara; de la Rosa-Díaz, Jesús J.; Huerta-Arellano, Vladimir; Marroquín-Fernández, Marco B.; Martínez-Riojas, L. Martin; López-Jiménez, Alejandro; Higham, Thomas; Willerslev, Eske (2020). "Evidence of human occupation in Mexico around the Last Glacial Maximum". Nature. 584 (7819): 87–92. Bibcode:2020Natur.584...87A. doi:10.1038/s41586-020-2509-0. PMID 32699412. S2CID 220697089.
  20. ^ Becerra-Valdivia, Lorena; Higham, Thomas (2020). "The timing and effect of the earliest human arrivals in North America". Nature. 584 (7819): 93–97. Bibcode:2020Natur.584...93B. doi:10.1038/s41586-020-2491-6. PMID 32699413. S2CID 220715918.
  21. ^ Gruhn, Ruth (22 July 2020). "Evidence grows that peopling of the Americas began more than 20,000 years ago". Nature. 584 (7819): 47–48. Bibcode:2020Natur.584...47G. doi:10.1038/d41586-020-02137-3. PMID 32699366. S2CID 220717778.
  22. ^ Spencer Wells (2006). Deep Ancestry: Inside the Genographic Project. National Geographic Books. pp. 222–. ISBN 978-0-7922-6215-2. OCLC 1031966951.
  23. ^ John H. Relethford (17 January 2017). 50 Great Myths of Human Evolution: Understanding Misconceptions about Our Origins. John Wiley & Sons. pp. 192–. ISBN 978-0-470-67391-1. OCLC 1238190784.
  24. ^ H. James Birx, ed. (10 June 2010). 21st Century Anthropology: A Reference Handbook. SAGE Publications. ISBN 978-1-4522-6630-5. OCLC 1102541304.
  25. ^ John E Kicza; Rebecca Horn (3 November 2016). Resilient Cultures: America's Native Peoples Confront European Colonialization 1500-1800 (2 ed.). Routledge. ISBN 978-1-315-50987-7.
  26. ^ Baisas, Laura (November 16, 2022). "Scientists still are figuring out how to age the ancient footprints in White Sands National Park". Popular Science. Retrieved September 18, 2023.
  27. ^ Somerville, Andrew D.; Casar, Isabel; Arroyo-Cabrales, Joaquín (2021). "New AMS Radiocarbon Ages from the Preceramic Levels of Coxcatlan Cave, Puebla, Mexico: A Pleistocene Occupation of the Tehuacan Valley?". Latin American Antiquity. 32 (3): 612–626. doi:10.1017/laq.2021.26.
  28. ^ a b Chatters, James C.; Potter, Ben A.; Prentiss, Anna Marie; Fiedel, Stuart J.; Haynes, Gary; Kelly, Robert L.; Kilby, J. David; Lanoë, François; Holland-Lulewicz, Jacob; Miller, D. Shane; Morrow, Juliet E.; Perri, Angela R.; Rademaker, Kurt M.; Reuther, Joshua D.; Ritchison, Brandon T.; Sanchez, Guadalupe; Sánchez-Morales, Ismael; Spivey-Faulkner, S. Margaret; Tune, Jesse W.; Haynes, C. Vance (October 23, 2021). "Evaluating Claims of Early Human Occupation at Chiquihuite Cave, Mexico". PaleoAmerica. 8 (1). Informa UK Limited: 1–16. doi:10.1080/20555563.2021.1940441. ISSN 2055-5563. S2CID 239853925.
  29. ^ a b Bryant, Vaughn M. Jr. (1998). "Pre-Clovis". In Guy Gibbon; et al. (eds.). Archaeology of Prehistoric Native America: An Encyclopedia. Garland reference library of the humanities. Vol. 1537. pp. 682–683. ISBN 978-0-8153-0725-9.
  30. ^ Hunt, Katie (2023-10-05). "Scientists say they've confirmed evidence that humans arrived in the Americas far earlier than previously thought". CNN. Retrieved 2024-07-22.
  31. ^ a b c d e f g h Brigham-Grette, Julie; Lozhkin, Anatoly V.; Anderson, Patricia M. & Glushkova, Olga Y. (2004). "Paleoenvironmental Conditions in West Beringia Before the Last Glacial Maximum". In D.B. Madsen (ed.). Entering America: Northeast Asia and Beringia Before the Last Glacial Maximum. University of Utah Press. ISBN 978-0-87480-786-8.
  32. ^ a b c d e f g Jackson, Lionel E. Jr. & Wilson, Michael C. (February 2004). "The Ice-Free Corridor Revisited". Geotimes. American Geological Institute.
  33. ^ a b c d e Jackson, L.E. Jr.; Phillips, F.M.; Shimamura, K. & Little, E.C. (1997). "Cosmogenic 36Cl dating of the Foothills Erratics train, Alberta, Canada". Geology. 25 (3): 195–198. Bibcode:1997Geo....25..195J. doi:10.1130/0091-7613(1997)025<0195:ccdotf>2.3.co;2.
  34. ^ a b c d e f g h i j k Mandryk, Carole A.S.; Josenhans, Heiner; Fedje, Daryl W. & Mathewes, Rolf W. (January 2001). "Late Quaternary paleoenvironments of Northwestern North America: implications for inland versus coastal migration routes". Quaternary Science Reviews. 20 (1): 301–314. Bibcode:2001QSRv...20..301M. doi:10.1016/s0277-3791(00)00115-3.
  35. ^ a b Dyke, A.S.; Moore, A. & Robertson, L. (2003). Deglaciation of North America (Report). Open File 1574. Geological Survey of Canada. doi:10.4095/214399.
  36. ^ a b Booth, Derek B.; Troost, Kathy Goetz; Clague, John J. & Waitt, Richard B. (2003). "The Cordilleran Ice Sheet". The Quaternary Period in the United States. Developments in Quaternary Sciences. Vol. 1. pp. 17–43. doi:10.1016/S1571-0866(03)01002-9. ISBN 978-0-4445-1470-7.
  37. ^ a b Blaise, B.; Clague, J.J. & Mathewes, R.W. (1990). "Time of maximum Late Wisconsin glaciation, west coast of Canada". Quaternary Research. 34 (3): 282–295. Bibcode:1990QuRes..34..282B. doi:10.1016/0033-5894(90)90041-i. S2CID 129658495.
  38. ^ Misarti, Nicole; Finney, Bruce P.; Jordan, James W.; et al. (10 August 2012). "Early retreat of the Alaska Peninsula Glacier Complex and the implications for coastal migrations of First Americans". Quaternary Science Reviews. 48: 1–6. Bibcode:2012QSRv...48....1M. doi:10.1016/j.quascirev.2012.05.014.
  39. ^ a b c d e Clague, John J.; Mathewes, Rolf W. & Ager, Thomas A. (2004). "Environments of Northwestern North America before the Last Glacial Maximum". In D.B. Madsen (ed.). Entering America: Northeast Asia and Beringia Before the Last Glacial Maximum. University of Utah Press. ISBN 978-0-87480-786-8.
  40. ^ a b c d e f Vasil'ev, Sergey A.; Kuzmin, Yaroslav V.; Orlova, Lyubov A. & Dementiev, Vyacheslav N. (2002). "Radiocarbon-based chronology of the Paleolithic in Siberia and its relevance to the peopling of the New World". Radiocarbon. 44 (2): 503–530. Bibcode:2002Radcb..44..503V. doi:10.1017/s0033822200031878.
  41. ^ a b c Graf, Kelly E. (2009). "Modern Human Colonization of the Siberian Mammoth Steppe: A View from South-Central Siberia" (PDF). In Marta Camps; Parth Chauhan (eds.). Sourcebook of Paleolithic Transitions. Springer. pp. 479–501. doi:10.1007/978-0-387-76487-0_32. ISBN 978-0-387-76478-8.
  42. ^ a b c d e Fedje, Daryl W.; Mackie, Quentin; Dixon, E. James & Heaton, Timothy H. (2004). "Late Wisconsin Environment and Archaeological Visibility along the Northern Northwest Coast". In D.B. Madsen (ed.). Entering America: Northeast Asia and Beringia Before the Last Glacial Maximum. University of Utah Press. ISBN 978-0-87480-786-8.
  43. ^ a b c d e Erlandson, Jon M. & Braje, Todd J. (2011). "From Asia to the Americas by boat? Paleogeography, paleoecology, and stemmed points of the northwest Pacific". Quaternary International. 239 (1–2): 28–37. Bibcode:2011QuInt.239...28E. doi:10.1016/j.quaint.2011.02.030.
  44. ^ a b c Erlandson, Jon M.; Graham, Michael H.; Bourque, Bruce J.; et al. (2007). "The Kelp highway hypothesis: marine ecology, the coastal migration theory, and the peopling of the Americas". The Journal of Island and Coastal Archaeology. 2 (2): 161–174. Bibcode:2007JICA....2..161E. doi:10.1080/15564890701628612. S2CID 140188874.
  45. ^ a b c Vachula, R.S.; Huang, Y.; Russell, J. M.; et al. (20 May 2020). "Sedimentary biomarkers reaffirm human impacts on northern Beringian ecosystems during the Last Glacial period". Boreas. 49 (3): 514–525. Bibcode:2020Borea..49..514V. doi:10.1111/bor.12449.
  46. ^ a b c Vachula, R.S.; Huang, Y.; Longo, W. M.; et al. (13 December 2018). "Evidence of Ice Age humans in eastern Beringia suggests early migration to North America". Quaternary Science Reviews. 205: 35–44. doi:10.1016/j.quascirev.2018.12.003. S2CID 134519782.
  47. ^ a b Kaplan, Sarah (October 24, 2018). "Continent's oldest spear points provide new clues about the first Americans". Washington Post.
  48. ^ a b c d e Dillehay, Thomas (2000). The Settlement of the Americas: A New Prehistory. New York: Basic Books. ISBN 978-0-465-07669-7.
  49. ^ a b Zimmer, Carl (23 September 2021). "Ancient Footprints Push Back Date of Human Arrival in the Americas". The New York Times. Retrieved 23 September 2021.
  50. ^ a b Matthew Bennett; et al. (23 September 2021). "Evidence of humans in North America during the Last Glacial Maximum". Science. 373 (6562): 1528–1531. Bibcode:2021Sci...373.1528B. doi:10.1126/science.abg7586. PMID 34554787. S2CID 237616125. Retrieved 24 September 2021.
  51. ^ Figure 4 of Andrew, Kitchen (2008). "A Three-Stage Colonization Model for the Peopling of the Americas". PLOS ONE. 3 (2): e1596. Bibcode:2008PLoSO...3.1596K. doi:10.1371/journal.pone.0001596. PMC 2223069. PMID 18270583.
  52. ^ White, Phillip M. (2006). American Indian chronology: chronologies of the American mosaic. Greenwood. p. 1. ISBN 978-0-313-33820-5.
  53. ^ a b c d Wells, Spencer & Read, Mark (2002). The Journey of Man - A Genetic Odyssey. Random House. pp. 138–140. ISBN 978-0-8129-7146-0.
  54. ^ Lovgren, Stefan (March 13, 2008). "Americas Settled 15,000 Years Ago, Study Says". National Geographic. Archived from the original on March 14, 2008.
  55. ^ a b c d Bonatto, Sandro L. & Salzano, Francisco M. (1997). "A single and early migration for the peopling of the Americas supported by mitochondrial DNA sequence data". Proceedings of the National Academy of Sciences. 94 (5): 1866–1871. Bibcode:1997PNAS...94.1866B. doi:10.1073/pnas.94.5.1866. PMC 20009. PMID 9050871.
  56. ^ a b Cinq-Mars, J. (1979). "Bluefish Cave 1: A Late Pleistocene Eastern Beringian Cave Deposit in the Northern Yukon". Canadian Journal of Archaeology (3): 1–32. JSTOR 41102194.
  57. ^ a b Bonnichsen, Robson (1978). "Critical arguments for Pleistocene artifacts from the Old Crow basin, Yukon: a preliminary statement". In Alan L. Bryan (ed.). Early Man in America from a Circum-Pacific Perspective. Occasional Papers No. 1. Edmonton: Archaeological Researches International Department of Anthropology, University of Alberta. pp. 102–118. ISBN 978-0-88864-999-7.
  58. ^ a b c Oppenheimer, Stephen. "Journey of mankind". Bradshaw Foundation.
  59. ^ a b c Goodyear, Albert C. (2005). "Evidence of Pre-Clovis sites in the eastern United States". In Robson Bonnichsen; et al. (eds.). Paleoamerican Origins: Beyond Clovis. Peopling of the Americas. Center for the Study of the First Americans, Texas A&M University. pp. 103–112. ISBN 978-1-60344-812-3.
  60. ^ Pedersen, Mikkel W.; Ruter, Anthony; Schweger, Charles; et al. (August 10, 2016). "Postglacial viability and colonization in North America's ice-free corridor". Nature. 537 (7618): 45–49. Bibcode:2016Natur.537...45P. doi:10.1038/nature19085. PMID 27509852. S2CID 4450936.
  61. ^ Chung, Emily (August 10, 2016). "Popular theory on how humans populated North America can't be right, study shows: Ice-free corridor through Alberta, B.C. not usable by humans until after Clovis people arrived". CBC News. Retrieved August 10, 2016.
  62. ^ Goebel, Ted & Buvit, Ian (2011). From the Yenisei to the Yukon: Interpreting Lithic Assemblage Variability in Late Pleistocene/Early Holocene Beringia. Center for the Study of the First Americans, Texas A&M University Press. p. 5. ISBN 978-1-60344-384-5.
  63. ^ Morlan, Richard E. (March 4, 2015). "Old Crow Basin". The Canadian Encyclopedia. Historica Canada.
  64. ^ Handwerk, Brian (22 July 2020). "Discovery in Mexican Cave May Drastically Change the Known Timeline of Humans' Arrival to the Americas". Smithsonian Magazine.
  65. ^ Costopoulos, Andre (November 10, 2021). "30ky old archaeological material at Chiquihuite Cave, round 2: It still doesn't matter how much some of the objects look like stone tools". ArcheoThoughts. Retrieved September 16, 2023.
  66. ^ "Were humans living in a Mexican cave during the last ice age?".
  67. ^ Vialou, D.; Feathers; Fontugne; Vialou (2017). "Peopling South America's centre: the late Pleistocene site of Santa Elina" (PDF). Antiquity. 91 (358): 865–884. doi:10.15184/aqy.2017.101.
  68. ^ Rodrigues, Cheliz; Giannini (2003). "Early anthropic occupation and geomorphological changes in South America: human–environment interactions and OSL data from the Rincão I site , southeastern Brazil". Journal of Quaternary Science. 38 (5): 685–701. doi:10.1002/jqs.3505. S2CID 258572647.
  69. ^ Santos, G.M; Bird, M.I; Parenti, F.; et al. (2003). "A revised chronology of the lowest occupation layer of Pedra Furada Rock Shelter, Piauı́, Brazil: The Pleistocene peopling of the Americas" (PDF). Quaternary Science Reviews. 22 (21–22): 2303–2310. Bibcode:2003QSRv...22.2303S. doi:10.1016/S0277-3791(03)00205-1.
  70. ^ van Vark, G.N.; Kuizenga, D. & Williams, F.L. (June 2003). "Kennewick and Luzia: lessons from the European Upper Paleolithic". American Journal of Physical Anthropology. 121 (2): 181–184, discussion 185–188. doi:10.1002/ajpa.10176. PMID 12740961.
     Fiedel, Stuart J. (2004). "The Kennewick Follies: 'New' Theories about the Peopling of the Americas". Journal of Anthropological Research. 60 (1): 75–110. doi:10.1086/jar.60.1.3631009. JSTOR 3631009. S2CID 163722475.
     González-José, R.; Bortolini, M.C.; Santos, F.R. & Bonatto, S.L. (October 2008). "The peopling of America: craniofacial shape variation on a continental scale and its interpretation from an interdisciplinary view". American Journal of Physical Anthropology. 137 (2): 175–187. doi:10.1002/ajpa.20854. hdl:11336/101290. PMID 18481303. S2CID 32748672.
  71. ^ Moreno-Mayar, J. Víctor; Vinner, Lasse; de Barros Damgaard, Peter; de la Fuente, Constanza; et al. (7 December 2018). "Early human dispersals within the Americas". Science. 362 (6419): eaav2621. Bibcode:2018Sci...362.2621M. doi:10.1126/science.aav2621. PMID 30409807.
  72. ^ Posth, Cosimo; Nakatsuka, Nathan; Lazaridis, Iosif; Skoglund, Pontus; et al. (15 November 2018). "Reconstructing the Deep Population History of Central and South America". Cell. 175 (5): 1185–1197.e22. doi:10.1016/j.cell.2018.10.027. ISSN 0092-8674. PMC 6327247. PMID 30415837.
  73. ^ Holen, Steven R.; Deméré, Thomas A.; Fisher, Daniel C.; et al. (2017). "A 130,000-year-old archaeological site in southern California, USA". Nature. 544 (7651): 479–483. Bibcode:2017Natur.544..479H. doi:10.1038/nature22065. PMID 28447646. S2CID 205255425.
  74. ^ Rincon, Paul (26 April 2017). "First Americans claim sparks controversy". BBC News. Retrieved 30 April 2017. Michael R. Waters commented that "To demonstrate such early occupation of the Americas requires the presence of unequivocal stone artifacts. There are no unequivocal stone tools associated with the bones... this site is likely just an interesting paleontological locality." Chris Stringer said that "extraordinary claims require extraordinary evidence – each aspect requires the strongest scrutiny," adding that "High and concentrated forces must have been required to smash the thickest mastodon bones, and the low energy depositional environment seemingly provides no obvious alternative to humans using the heavy cobbles found with the bones.
  75. ^ Pitulko, V.V.; Nikolsky, P.A.; Girya, E. Yu; et al. (2 January 2004). "The Yana RHS Site: Humans in the Arctic Before the Last Glacial Maximum". Science. 303 (5654): 52–56. Bibcode:2004Sci...303...52P. doi:10.1126/science.1085219. ISSN 0036-8075. PMID 14704419. S2CID 206507352.
  76. ^ a b c d e f Tamm, Erika; Kivisild, Toomas; Reidla, Maere; et al. (2007). "Beringian Standstill and Spread of Native American Founders". PLOS ONE. 2 (9): e829. Bibcode:2007PLoSO...2..829T. doi:10.1371/journal.pone.0000829. PMC 1952074. PMID 17786201.
  77. ^ a b c d Kitchen, Andrew; Miyamoto, Michal M. & Mulligan, Connie J. (2008). "A Three-Stage Colonization Model for the Peopling of the Americas". PLOS ONE. 3 (2): e1596. Bibcode:2008PLoSO...3.1596K. doi:10.1371/journal.pone.0001596. PMC 2223069. PMID 18270583.
  78. ^ Wei-Haas, Maya (5 October 2023). "New Evidence That Ancient Footprints Push Back Human Arrival in North America - Following up on a study in 2021 of tracks found in New Mexico, researchers used more methods to bolster the claim that the tracks are up to 23,000 years old". The New York Times. Archived from the original on 5 October 2023. Retrieved 6 October 2023.
  79. ^ Pigati, Jeffrey S.; et al. (5 October 2023). "Independent age estimates resolve the controversy of ancient human footprints at White Sands". Science. 382 (6666): 73–75. Bibcode:2023Sci...382...73P. doi:10.1126/science.adh5007. PMID 37797035. S2CID 263672291. Archived from the original on 7 October 2023. Retrieved 6 October 2023.
  80. ^ Surovell 2022.
  81. ^ a b Skoglund, Pontus & Reich, David (December 2016). "A genomic view of the peopling of the Americas" (PDF). Current Opinion in Genetics & Development. 41: 27–35. doi:10.1016/j.gde.2016.06.016. PMC 5161672. PMID 27507099. Recently, we carried out a stringent test of the null hypothesis of a single founding population of Central and South Americans using genome-wide data from diverse Native Americans. We detected a statistically clear signal linking Native Americans in the Amazonian region of Brazil to present-day Australo-Melanesians and Andaman Islanders ('Australasians'). Specifically, we found that Australasians share significantly more genetic variants with some Amazonian populations—including ones speaking Tupi languages—than they do with other Native Americans. We called this putative ancient Native American lineage "Population Y" after Ypykuéra, which means 'ancestor' in the Tupi language family.
  82. ^ a b c Kemp, Brian M.; Malhi, Ripan S.; McDonough, John; et al. (2007). "Genetic Analysis of Early Holocene Skeletal Remains From Alaska and its Implications for the Settlement of the Americas" (PDF). American Journal of Physical Anthropology. 132 (4): 605–621. CiteSeerX 10.1.1.576.7832. doi:10.1002/ajpa.20543. PMID 17243155.
  83. ^ a b c d e Perego, Ugo A.; Achilli, Alessandro; Angerhofer, Norman; et al. (2009). "Distinctive Paleo-Indian Migration Routes from Beringia Marked by Two Rare mtDNA Haplogroups". Current Biology. 19 (1): 1–8. Bibcode:2009CBio...19....1P. doi:10.1016/j.cub.2008.11.058. PMID 19135370. S2CID 9729731.
  84. ^ a b Derenko, Miroslava; Malyarchuk, Boris; Grzybowski, Tomasz; et al. (December 21, 2010). "Origin and Post-Glacial Dispersal of Mitochondrial DNA Haplogroups C and D in Northern Asia". PLOS ONE. 5 (12): e15214. Bibcode:2010PLoSO...515214D. doi:10.1371/journal.pone.0015214. PMC 3006427. PMID 21203537.
  85. ^ Bortolini, Maria-Catira; Salzano, Francisco M.; Thomas, Mark G.; et al. (2003). "Y-chromosome evidence for differing ancient demographic histories in the Americas" (PDF). American Journal of Human Genetics. 73 (3): 524–539. doi:10.1086/377588. PMC 1180678. PMID 12900798.
  86. ^ Moreno-Mayar, J. Víctor; Potter, Ben A.; Vinner, Lasse; Steinrücken, Matthias; Rasmussen, Simon; Terhorst, Jonathan; Kamm, John A.; Albrechtsen, Anders; Malaspinas, Anna-Sapfo; Sikora, Martin; Reuther, Joshua D.; Irish, Joel D.; Malhi, Ripan S.; Orlando, Ludovic; Song, Yun S.; Nielsen, Rasmus; Meltzer, David J.; Willerslev, Eske (2018), "Terminal Pleistocene Alaskan genome reveals first founding population of Native Americans", Nature, 553 (7687), Macmillan Publishers Limited: 203–207, Bibcode:2018Natur.553..203M, doi:10.1038/nature25173, PMID 29323294, S2CID 4454580, retrieved January 3, 2018
  87. ^ Confidence intervals given in Moreno-Mayar et al. (2018):
    • 26.1-23-9 kya for the separation of the East Asian lineage of ANA from modern East Asian populations;
    • 25-20 kya for the admixture event of ANE and early East Asian lineages ancestral to ANA;
    • 22.0-18.1 kya for the separation of Ancient Beringian from other Paleo-Indian lineages;
    • 17.5-14.6 kya for the separation of Paleo Indian into North Native Americans (NNA) and South Native Americans (SNA).
  88. ^ Castro e Silva, Marcos Araújo; Ferraz, Tiago; Bortolini, Maria Cátira; Comas, David; Hünemeier, Tábita (2021-04-06). "Deep genetic affinity between coastal Pacific and Amazonian natives evidenced by Australasian ancestry". Proceedings of the National Academy of Sciences. 118 (14). doi:10.1073/pnas.2025739118. ISSN 0027-8424. PMC 8040822. PMID 33782134.
  89. ^ Posth, Cosimo; Nakatsuka, Nathan; Lazaridis, Iosif; Skoglund, Pontus; Mallick, Swapan; Lamnidis, Thiseas C.; Rohland, Nadin; Nägele, Kathrin; Adamski, Nicole; Bertolini, Emilie; Broomandkhoshbacht, Nasreen; Cooper, Alan; Culleton, Brendan J.; Ferraz, Tiago; Ferry, Matthew (2018-11-15). "Reconstructing the Deep Population History of Central and South America". Cell. 175 (5): 1185–1197.e22. doi:10.1016/j.cell.2018.10.027. ISSN 0092-8674. PMC 6327247. PMID 30415837.
  90. ^ Heintzman, Peter D.; Froese, Duane; Ives, John W.; Soares, André E. R.; Zazula, Grant D.; Letts, Brandon; Andrews, Thomas D.; Driver, Jonathan C.; Hall, Elizabeth; Hare, P. Gregory; Jass, Christopher N. (2016-07-19). "Bison phylogeography constrains dispersal and viability of the Ice Free Corridor in western Canada". Proceedings of the National Academy of Sciences. 113 (29): 8057–8063. doi:10.1073/pnas.1601077113. ISSN 0027-8424. PMID 27274051.
  91. ^ Society, National Geographic (2019-08-19). "Hunter-Gatherer Culture". National Geographic Society. Retrieved 2022-02-18.
  92. ^ Leonard, Jennifer A.; Vilà, Carles; Fox-Dobbs, Kena; Koch, Paul L.; Wayne, Robert K.; Van Valkenburgh, Blaire (2007-07-03). "Megafaunal Extinctions and the Disappearance of a Specialized Wolf Ecomorph". Current Biology. 17 (13): 1146–1150. doi:10.1016/j.cub.2007.05.072. ISSN 0960-9822.
  93. ^ a b Yang, Melinda A. (2022-01-06). "A genetic history of migration, diversification, and admixture in Asia". Human Population Genetics and Genomics. 2 (1): 1–32. doi:10.47248/hpgg2202010001. ISSN 2770-5005. " Raghavan et al. [51] used outgroup f3-statistics to show that Mal'ta1 was most closely related to present-day Native Americans. This pattern led to a model in which the dispersal of humans to the Americas originated in a population in Siberia derived from a mixture of two distinct ancestries, one associated with East Asians today and another associated with Mal'ta1. Recent studies of DNA from ancient Siberians [69,73] provided direct evidence of admixed populations in Siberia that are closely related to the Native American lineage."
  94. ^ Zhang, Xiaoming; Ji, Xueping; Li, Chunmei; Yang, Tingyu; Huang, Jiahui; Zhao, Yinhui; Wu, Yun; Ma, Shiwu; Pang, Yuhong; Huang, Yanyi; He, Yaoxi; Su, Bing (2022-07-25). "A Late Pleistocene human genome from Southwest China". Current Biology. 32 (14): 3095–3109.e5. Bibcode:2022CBio...32E3095Z. doi:10.1016/j.cub.2022.06.016. ISSN 0960-9822. PMID 35839766. S2CID 250502011.
  95. ^ Raff, Jennifer (8 February 2022). Origin: A Genetic History of the Americas. Grand Central Publishing. p. 188. ISBN 978-1-5387-4970-8. "Current estimates suggest that approximately 63% of the First Peoples' ancestry comes from the East Asian group and the rest from the Ancient North Siberians. We're not sure where this interaction took place. Some archaeologists believe that it occurred in East Asia, suggesting that this is where the Siberians moved during the LGM" [...] "There's also a case to be made for this interaction having taken place bear the Lake Baikal region in Siberia from genetic evidence, too" [...] "But other archaeologists and geneticists argue that the meeting of the two grandparent populations of Native Americans occurred because people moved north, not south, in response to the LGM"
  96. ^ Raff 2022, p. 188: "Mal'ta's population -- the ancient Northern Siberians, seems to have encountered the daughter East Asian population described at the beginning of this chapter around 25,000 years ago and interbred with them."..."We're not sure where this interaction took place. Some archaeologists believe that it occurred in East Asia, suggesting that this is where the Siberians moved during the LGM"..."There's also a case to be made for this interaction having taken place bear the Lake Baikal region in Siberia from genetic evidence, too. The ancient Paleo-Siberians, as mentioned earlier in this chapter, split from the East Asian ancestors of Native Americans by about 25,000 years ago. They are known to us from the genomes of an Upper Paleolithic person from the Lake Baikal region known to us from the genomes of an Upper Paleolithic from the Lake Baikal region known as UKY and a person from Northeastern Siberia dating to about 9,800 years ago known as Kolyma1."
  97. ^ Raff 2022, pp. 188–189: "But other archaeologists and geneticists argue that the meeting of the two grandparent populations of Native Americans occurred because people moved north, not south, in response to the LGM. In this scenario, Paleo-Siberian descendants, like UKY, could have been the result of a southward repopulation of Siberia out of Beringia. The reason for this is because both mitochondrial and nuclear genomes of Native Americans show that they had been isolated from all other populations for a prolonged period of time, during which they developed the genetic traits found only in Native American populations. This finding, initially based on classical genetic markers and mitochondrial evidence, came to be known as the Beringian Incubation, the Beringian Pause or the Beringian Standstill hypothesis."
  98. ^ Grebenyuk, Pavel S.; Fedorchenko, Alexander Yu.; Dyakonov, Viktor M.; Lebedintsev, Alexander I.; Malyarchuk, Boris A. (2022). "Ancient Cultures and Migrations in Northeastern Siberia". Humans in the Siberian Landscapes. Springer Geography. Springer International Publishing. p. 96. doi:10.1007/978-3-030-90061-8_4. ISBN 978-3-030-90060-1. According to the latest paleogenetic data, East Asian populations migrated to Northeastern Siberia ca. 20,000–18,000 cal BP. The migration was accompanied by their mixing with the descendants of the "Ancient North Siberians", represented by the genome from the Yana and Malta individuals. These processes were reflected in the Beringian tradition's wide proliferation in the region and led to the emergence of several ancestral lineages (Fig. 1) in Extreme Northeastern Asia: the Ancient Paleosiberian population represented by the genome of the individual from Duvanny Yar, and the ancestral Native Americans. The latter type subsequently divided into the Ancient Beringians and all other Native Americans (Moreno-Mayar et al. 2018; Sikora et al. 2019).
  99. ^ Hoffecker, John F. (4 March 2016). "Beringia and the global dispersal of modern humans: Beringia and the Global Dispersal of Modern Humans". Evolutionary Anthropology: Issues, News, and Reviews. 25 (2): 64–78. doi:10.1002/evan.21478. PMID 27061035. S2CID 3519553. "The pattern observed in the mtDNA data by Tamm and colleagues has yet to emerge with equal clarity in either Y-DNA or autosomal DNA. The lack of a similar pattern in the Y-DNA data conceivably reflects different histories of the paternal and maternal lineages—a pattern found in other parts of the world (e.g., southern Asia).33 Some support for the standstill hypothesis in autosomal DNA may be found in the distribution of an allele at a microsatellite locus on chromosome 9 (D9S1120) which exhibits a pattern similar to that seen in the mtDNA data.34"
  100. ^ Sikora, Martin; Pitulko, Vladimir V.; Sousa, Vitor C.; et al. (2019). "The population history of northeastern Siberia since the Pleistocene". Nature. 570 (7760): 182–188. Bibcode:2019Natur.570..182S. doi:10.1038/s41586-019-1279-z. hdl:1887/3198847. PMID 31168093. S2CID 174809069.
  101. ^ Zhang, Xiaoming; Ji, Xueping; Li, Chunmei; Yang, Tingyu; Huang, Jiahui; Zhao, Yinhui; Wu, Yun; Ma, Shiwu; Pang, Yuhong; Huang, Yanyi; He, Yaoxi; Su, Bing (July 2022). "A Late Pleistocene human genome from Southwest China". Current Biology. 32 (14): 3095–3109.e5. Bibcode:2022CBio...32E3095Z. doi:10.1016/J.CUB.2022.06.016. ISSN 0960-9822. PMID 35839766. S2CID 250502011.
  102. ^ "DNA from ancient population in Southern China suggests Native Americans' East Asian roots".
  103. ^ a b c d Adachi, Noboru; Shinoda, Ken-ichi; Umetsu, Kazuo & Matsumura, Hirofumi (March 2009). "Mitochondrial DNA analysis of Jōmon skeletons from the Funadomari site, Hokkaido, and its implication for the origins of Native American". American Journal of Physical Anthropology. 138 (3): 255–265. doi:10.1002/ajpa.20923. PMID 18951391.
  104. ^ a b Schurr, Theodore G. (May 2000). "Mitochondrial DNA and the Peopling of the New World" (PDF). American Scientist. 88 (3): 246. Bibcode:2000AmSci..88..246S. doi:10.1511/2000.3.246. S2CID 7527715.
  105. ^ Zakharov, I.A.; Derenko, M.V.; Maliarchuk, B.A.; et al. (12 January 2006). "Mitochondrial DNA variation in the aboriginal populations of the Altai-Baikal region: implications for the genetic history of North Asia and America". Annals of the New York Academy of Sciences. 1011 (1): 21–35. Bibcode:2004NYASA1011...21Z. doi:10.1196/annals.1293.003. PMID 15126280. S2CID 37139929.
  106. ^ a b c d e Starikovskaya, Elena B.; Sukernik, Rem I.; Derbeneva, Olga A.; et al. (January 2005). "Mitochondrial DNA diversity in indigenous populations of the southern extent of Siberia, and the origins of Native American haplogroups". Annals of Human Genetics. 69 (Pt 1): 67–89. doi:10.1046/j.1529-8817.2003.00127.x. PMC 3905771. PMID 15638829.
  107. ^ Adachi, Noboru; Shinoda, Ken-ichi; Umetsu, Kazuo; et al. (November 2011). "Mitochondrial DNA analysis of Hokkaido Jōmon skeletons: Remnants of archaic maternal lineages at the southwestern edge of former Beringia". American Journal of Physical Anthropology. 146 (3): 346–360. doi:10.1002/ajpa.21561. PMID 21953438.
  108. ^ Scatena, Roberto; Bottoni, Patrizia; Giardina, Bruno (8 March 2012). Advances in Mitochondrial Medicine. Springer Science & Business Media. p. 446. ISBN 978-94-007-2869-1.
  109. ^ Raff, Jennifer A.; Bolnick, Deborah A. (October 2015). "Does Mitochondrial Haplogroup X Indicate Ancient Trans-Atlantic Migration to the Americas? A Critical Re-Evaluation". PaleoAmerica. 1 (4): 297–304. doi:10.1179/2055556315Z.00000000040. ISSN 2055-5563. S2CID 85626735. "These studies have all reached the same conclusion and suggest that haplogroup X2a is likely to have originated in the same population(s) as the other American founder haplogroups, by virtue of having comparable coalescence dates and demographic histories" ... "X2a has not been found anywhere in Eurasia, and phylogeography gives us no compelling reason to think it is more likely to come from Europe than from Siberia. Furthermore, analysis of the complete genome of Kennewick Man, who belongs to the most basal lineage of X2a yet identified, gives no indication of recent European ancestry and moves the location of the deepest branch of X2a to the West Coast, consistent with X2a belonging to the same ancestral population as the other founder mitochondrial haplogroups."
  110. ^ Li, Hong-Chuan; Biggar, Robert J.; Miley, Wendell J.; et al. (2004). "Provirus load in breast milk and risk of mother-to-child transmission of Human T Lymphotropic Virus Type I". The Journal of Infectious Diseases. 190 (7): 1275–1278. doi:10.1086/423941. PMID 15346338.
  111. ^ a b c d Verdonck, K.; González, E.; Van Dooren, S.; et al. (April 2007). "Human T-lymphotropic virus 1: recent knowledge about an ancient infection". The Lancet Infectious Diseases. 7 (4): 266–281. doi:10.1016/S1473-3099(07)70081-6. PMID 17376384.
  112. ^ Gessain, A.; Gallo, R.C. & Franchini, G. (April 1992). "Low degree of human T-cell leukemia/lymphoma virus type I genetic drift in vivo as a means of monitoring viral transmission and movement of ancient human populations". Journal of Virology. 66 (4): 2288–2295. doi:10.1128/JVI.66.4.2288-2295.1992. PMC 289023. PMID 1548762.
  113. ^ Ishida, Takafumi; Yamamoto, Kohtaro; Omoto, Keiichi; et al. (September 1985). "Prevalence of a human retrovirus in native Japanese: evidence for a possible ancient origin". Journal of Infection. 11 (2): 153–157. doi:10.1016/s0163-4453(85)92099-7. PMID 2997332.
  114. ^ a b Miura, T.; Fukunaga, T.; Igarashi, T.; et al. (February 1994). "Phylogenetic subtypes of human T-lymphotropic virus type I and their relations to the anthropological background". Proceedings of the National Academy of Sciences of the United States of America. 91 (3): 1124–1127. Bibcode:1994PNAS...91.1124M. doi:10.1073/pnas.91.3.1124. PMC 521466. PMID 8302841.
  115. ^ Picard, F.J.; Coulthart, M.B.; Oger, J.; et al. (November 1995). "Human T-lymphotropic virus type 1 in coastal natives of British Columbia: phylogenetic affinities and possible origins". Journal of Virology. 69 (11): 7248–56. doi:10.1128/JVI.69.11.7248-7256.1995. PMC 189647. PMID 7474147.
  116. ^ Li, Hong-Chuan; Fujiyoshi, Toshinobu; Lou, Hong; et al. (December 1999). "The presence of ancient human T-cell lymphotropic virus type I provirus DNA in an Andean mummy". Nature Medicine. 5 (12): 1428–1432. doi:10.1038/71006. PMID 10581088. S2CID 12893136.
  117. ^ a b Coulthart, Michael B.; Posada, David; Crandall, Keith A. & Dekaband, Gregory A. (March 2006). "On the phylogenetic placement of human T cell leukemia virus type 1 sequences associated with an Andean mummy". Infection, Genetics and Evolution. 6 (2): 91–96. Bibcode:2006InfGE...6...91C. doi:10.1016/j.meegid.2005.02.001. PMC 1983367. PMID 16503510.
  118. ^ a b Gonzaleza, Silvia; Huddart, David; Israde-Alcántara, Isabel; et al. (30 March 2015). "Paleoindian sites from the Basin of Mexico: Evidence from stratigraphy, tephrochronology and dating" (PDF). Quaternary International. 363: 4–19. Bibcode:2015QuInt.363....4G. doi:10.1016/j.quaint.2014.03.015.
  119. ^ a b González-José, Rolando; González-Martín, Antonio; Hernández, Miquel; et al. (4 September 2003). "Craniometric evidence for Palaeoamerican survival in Baja California". Nature. 425 (6953): 62–65. Bibcode:2003Natur.425...62G. doi:10.1038/nature01816. PMID 12955139. S2CID 4423359.
  120. ^ Dillehay, Thomas D. (4 September 2003). "Tracking the first Americans". Nature. 425 (6953): 23–24. doi:10.1038/425023a. PMID 12955120. S2CID 4421265.
  121. ^ Fiedel, Stuart J. (Spring 2004). "The Kennewick follies: "new" theories about the peopling of the Americas". Journal of Anthropological Research. 60 (1): 75–110. doi:10.1086/jar.60.1.3631009. JSTOR 3631009. S2CID 163722475.
  122. ^ Chatters, James C.; Kennett, Douglas J.; Asmerom, Yemane; et al. (16 May 2014). "Late Pleistocene Human Skeleton and mtDNA Link Paleoamericans and Modern Native Americans" (PDF). Science. 344 (6185): 750–754. Bibcode:2014Sci...344..750C. doi:10.1126/science.1252619. PMID 24833392. S2CID 206556297. Archived from the original (PDF) on 2015-07-13.
  123. ^ Willerslev, Eske; Meltzer, David J. (17 June 2021). "Peopling of the Americas as inferred from ancient genomics". Nature. 594 (7863): 356–364. Bibcode:2021Natur.594..356W. doi:10.1038/s41586-021-03499-y. PMID 34135521. S2CID 235460793.
  124. ^ de Azvedo, Soledad; Bortolini, Maria C.; Bonatto, Sandro L.; et al. (January 2015). "Ancient Remains and the First Peopling of the Americas: Reassessing the Hoyo Negro Skull". American Journal of Physical Anthropology. 148 (3): 514–521. doi:10.1002/ajpa.22801. hdl:11336/42446. PMID 26174009.
     Azevedo, Soledad de; Quinto-Sánchez, Mirsha; Paschetta, Carolina & González-José, Rolando (28 February 2017). ""The first human settlement of the New World " A closer look at craniofacial variation and evolution of early and late Holocene Native American groups". Quaternary International. 431 (part B): 152–167. Bibcode:2017QuInt.431..152D. doi:10.1016/j.quaint.2015.11.012. hdl:11336/44745.
  125. ^ Seong, Chuntaek (December 2008). "Tanged points, microblades and late paleolithic hunting in Korea". Antiquity. 82 (318): 871–883. doi:10.1017/s0003598x00097647. S2CID 127994558.
  126. ^ Waters, Michael R. & Stafford, Thomas W. (23 February 2007). "Redefining the age of Clovis: implications for the peopling of the Americas". Science. 315 (5815): 1122–1126. Bibcode:2007Sci...315.1122W. doi:10.1126/science.1137166. PMID 17322060. S2CID 23205379.
  127. ^ Jenkins, Dennis L.; Davis, Loren G.; Stafford, Thomas W. Jr; et al. (13 July 2012). "Clovis Age Western Stemmed Projectile Points and Human Coprolites at the Paisley Caves". Science. 337 (6091): 223–228. Bibcode:2012Sci...337..223J. doi:10.1126/science.1218443. PMID 22798611. S2CID 40706795.
  128. ^ a b Adovasio, J. M; Donahue, J. & Stuckenrath, R. (1990). "The Meadowcroft Rockshelter Rasdiocarbon Chronology 1975–1990". American Antiquity. 55 (2): 348–354. doi:10.2307/281652. JSTOR 281652. S2CID 163541173.
  129. ^ Clark, Jorie; Carlson, Anders E.; Reyes, Alberto V.; Carlson, Elizabeth C. B.; Guillaume, Louise; Milne, Glenn A.; Tarasov, Lev; Caffee, Marc; Wilcken, Klaus; Rood, Dylan H. (2022-04-05). "The age of the opening of the Ice-Free Corridor and implications for the peopling of the Americas". Proceedings of the National Academy of Sciences. 119 (14): e2118558119. Bibcode:2022PNAS..11918558C. doi:10.1073/pnas.2118558119. ISSN 0027-8424. PMC 9168949. PMID 35312340.
  130. ^ Dobson, Jerome (et al.) (2021). The Bering Transitory Archipelago: Stepping Stones for the First Americans. Géoscience, 353, 55-65.
  131. ^ Altschul, Jeffrey; Johnson, William C.; Sterner, Matthew A.; Army Corps of Engineers, Los Angeles District; Army Corps of Engineers, Los Angeles District; Statistical Research, Inc.; SRI Press (1989). Deep Creek Site (CA-SBr-176): A Late Prehistoric Base Camp in the Mojave River Forks Region, San Bernardino County, California. Statistical Research Technical Series. Paul D. Bouey, Thomas M. Origer. Tucson, AZ: SRI Press.
  132. ^ a b Vajda, Edward J. (18 April 2017). "Dene-Yeniseian". Oxford Bibliographies Online. doi:10.1093/OBO/9780199772810-0064.
  133. ^ Flegontov, Pavel; Altınışık, N. Ezgi; Changmai, Piya; et al. (October 13, 2017). "Paleo-Eskimo genetic legacy across North America". bioRxiv: 203018. doi:10.1101/203018. hdl:21.11116/0000-0004-5D08-C. S2CID 90288469.
     Flegontov, Pavel; Altınışık, N. Ezgi; Changmai, Piya; et al. (5 June 2019). "Palaeo-Eskimo genetic ancestry and the peopling of Chukotka and North America" (PDF). Nature. 570 (7760): 236–240. Bibcode:2019Natur.570..236F. doi:10.1038/s41586-019-1251-y. ISSN 0028-0836. PMC 6942545. PMID 31168094.
  134. ^ Handwerk, Brian (February 12, 2010). "Face of Ancient Human Drawn From Hair's DNA; Genome paints picture of man from extinct Greenland culture". National Geographic News. Archived from the original on October 1, 2019.
  135. ^ Swisher, Mark (et al.). 2013. A Reassessment of the Role of the Canadian Ice-Free Corridor in Light of New Geological Evidence. Current Archaeological Happenings in Oregon Volume 38(4): 8-13.
  136. ^ Fladmark, Knute R. (January 1979). "Routes: alternate migration corridors for early man in North America". American Antiquity. 44 (1): 55–69. doi:10.2307/279189. JSTOR 279189. S2CID 162243347.
  137. ^ Callaway, Ewen (11 August 2016). "Plant and animal DNA suggests first Americans took the coastal route". Nature. 536 (7615): 138. Bibcode:2016Natur.536..138C. doi:10.1038/536138a. PMID 27510205.
  138. ^ Summer, Thomas (10 August 2016). "Humans may have taken different path into Americas than thought Arctic passage wouldn't have provided enough food for the earliest Americans' journey". Science News.
  139. ^ Rasmussen, Morten; Anzick, Sarah L.; Waters, Michael R.; Skoglund, Pontus; DeGiorgio, Michael; Stafford, Thomas W. Jr; et al. (February 2014). "The genome of a Late Pleistocene human from aClovis burial site in western Montana". Nature. 506 (7487): 225–229. Bibcode:2014Natur.506..225R. doi:10.1038/nature13025. PMC 4878442. PMID 24522598.
  140. ^ Gornitz, Vivian (January 2007). "Sea Level Rise, After the Ice Melted and Today". Goddard Institute for Space Studies. NASA. Archived from the original on 2007-02-02. Retrieved 23 April 2015.
  141. ^ Hetherington, Renée; Barrie, J. Vaughn; MacLeod, Roger & Wilson, Michael (February 2004). "Quest for the Lost Land". Geotimes.
  142. ^ "California islands give up evidence of early seafaring: Numerous artifacts found at late Pleistocene sites on the Channel Islands". Science Daily. University of Oregon. 3 March 2011.

Further reading

edit
edit